Inhibition of peripheral dopamine metabolism and the ventilatory response to hypoxia in the rat.

Dopamine (DA) is a putative neurotransmitter in the carotid body engaged in the generation of the hypoxic ventilatory response (HVR). However, the action of endogenous DA is unsettled. This study seeks to determine the ventilatory effects of increased availability of endogenous DA caused by inhibition of DA enzymatic breakdown. The peripheral inhibitor of MAO - debrisoquine, or COMT - entacapone, or both combined were injected to conscious rats. Ventilation and its responses to acute 8 % O(2) in N(2) were investigated in a whole body plethysmograph. We found that inhibition of MAO augmented the hyperventilatory response to hypoxia. Inhibition of COMT failed to influence the hypoxic response. However, simultaneous inhibition of both enzymes, the case in which endogenous availability of DA should increase the most, reversed the hypoxic augmentation of ventilation induced by MAO-inhibition. The inference is that when MAO alone is blocked, COMT takes over DA degradation in a compensatory way, which lowers the availability of DA, resulting in a higher intensity of the HVR. We conclude that MAO is the enzyme predominantly engaged in the chemoventilatory effects of DA. Furthermore, the findings imply that endogenous DA is inhibitory, rather than stimulatory, for hypoxic ventilation.

Validation of incorporating flurbiprofen into the Pittsburgh cocktail.

BACKGROUND: We have previously shown that flurbiprofen metabolism to 4'-hydroxyflurbiprofen provides an in vivo measure of cytochrome P450 (CYP) 2C9 activity. This study evaluated the possibility of incorporating flurbiprofen into the current 5-drug Pittsburgh cocktail. METHODS: In a randomized, 3-way, Latin-square, crossover-design study, 24 healthy subjects (mean age [+/-SD], 47.8 +/- 15.1 years) received flurbiprofen (50 mg) and the Pittsburgh 5-drug cocktail (100 mg caffeine, 100 mg mephenytoin, 10 mg debrisoquin [INN, debrisoquine], 250 mg chlorzoxazone, and 100 mg dapsone) separately and in combination on 3 occasions over a period of 5 weeks. Urine was collected from 0 to 8 hours, and plasma was obtained at 4 and 8 hours after drug administration. Parent drug and metabolite concentrations were measured to determine phenotypic indices for each of the metabolizing enzymes. RESULTS: The geometric mean ratio and 90% confidence interval of the phenotypic indices were included within the 80% to 125% bioequivalence range for each of the probe drugs. There were no statistically significant differences between the phenotypic indices determined after administration of the 5-drug and 6-drug cocktails. However, there was a small but statistically significant increase (7.5%, P = .03) in the 8-hour urinary flurbiprofen recovery ratio after administration of the 6-drug cocktail compared with that after administration of flurbiprofen alone. The 6-drug cocktail was well tolerated. CONCLUSION: The results of this study show that caffeine (CYP1A2), chlorzoxazone (CYP2E1), dapsone (N-acetyltransferase 2), debrisoquin (CYP2D6), flurbiprofen (CYP2C9), and mephenytoin (CYP2C19) can be simultaneously administered in low doses without metabolic interaction.

Methoxyphenamine O-demethylase and 5-hydroxylase: a GLC-ECD assay to study their activities and their inhibition by debrisoquine and sparteine.

A GLC-ECD method is described for the determination of the O-desmethyl, N-desmethyl and aromatic 5-hydroxy metabolites of methoxyphenamine in liver homogenates. The O-desmethyl and 5-hydroxy metabolites are deficient in poor metabolizers of debrisoquine and sparteine and the Dark Agouti rat model of this human phenotype. The present analytical method can be useful in determining methoxyphenamine O-demethylase and 5-hydroxylase activities as well as identifying those substrates which inhibit these and are worthy of further study.

Dopamine metabolism and disposition in schizophrenic patients. Studies using debrisoquin.

Debrisoquin sulfate, a monoamine oxidase inhibitor that does not enter the brain, was administered to 23 schizophrenic subjects. Plasma, cerebrospinal fluid (CSF), and urine samples were obtained before and during debrisoquin administration and were assayed for their content of norepinephrine and dopamine metabolites, ie, 3-methoxy-4-hydroxyphenylglycol (MHPG), homovanillic acid (HVA), and dihydroxyphenylacetic acid. The severity of the patient's schizophrenic symptoms was also assessed with several types of rating scales. During debrisoquin administration there were significant reductions in plasma, urine, and CSF MHPG levels. Regression analyses suggested that the reduction in CSF MHPG level was probably due to the reduction in plasma MHPG level, which contributes to the CSF MHPG pool. Debrisoquin administration was not associated with changes in CSF HVA level, although it did produce marked reductions in plasma and urinary HVA and dihydroxyphenylacetic acid levels. Significant correlations between plasma and CSF concentrations of HVA were noted during, but not before, debrisoquin administration. Before debrisoquin administration there were trends toward positive relationships between symptom severity and plasma HVA concentrations, which became stronger and statistically significant during debrisoquin administration. These data suggest that debrisoquin may be used as a research tool to create a condition in which measures of HVA in peripheral body fluids reflect dopamine system function and metabolism within the central nervous system.

Relationship between plasma aldosterone and angiotensin II before and after noradrenergic inhibition in normal subjects and patients with mild essential hypertension.

The responsiveness of plasma aldosterone to the infusion of angiotensin II at dose rates of 2, 4, and 10 ng/kg X min was assessed in 11 normal subjects and 13 patients with mild essential hypertension before and after 4 weeks of treatment with the sympatholytic agent debrisoquine. Debrisoquine treatment caused a significant (P less than 0.01) decrease in circulating norepinephrine (-45%), but did not modify plasma levels of angiotensin II, renin, aldosterone, or epinephrine or the metabolism of sodium or potassium. In normal subjects, debrisoquine caused a significant shift to the left (P less than 0.05) of the correlation relating plasma aldosterone to plasma angiotensin II levels. In patients with essential hypertension, the aldosterone-angiotensin II interrelationship was not modified. These findings suggest that the sympathetic nervous system exerts an inhibitory influence on aldosterone responsiveness to angiotensin II in normal man, and that this physiological interaction is impaired in patients with essential hypertension.

Acute effects of neuroleptics on unmedicated schizophrenic patients and controls.

Acute administration of haloperidol (0.2 mg/kg) produced many more side effects in normal controls than in unmedicated schizophrenic patients. Prior to the neuroleptic challenge, both groups were on the peripheral monoamine oxidase inhibitor, debrisoquin, for at least 1 week, in order to enhance the relative contribution of CNS catecholamine metabolites to those measured in both plasma and urine. The patient group had higher plasma levels of methoxyhydroxyphenylglycol (MHPG) and homovanillic acid (HVA) and higher urinary MHPG output than controls, but there were no effects of haloperidol challenge, compared to placebo challenge. In both groups there were significant declines in plasma HVA levels from 8:30 AM to 12 NOON. These declines were unaffected by the haloperidol challenge. Explanations for the marked differences in behavioral effects of haloperidol on patients and controls include the possibility that dopamine receptor numbers were increased in the brains of the schizophrenic patients.

Multiple pathways of propranolol's metabolism are inhibited by debrisoquin.

We investigated the effect of debrisoquin on propranolol metabolism in six normal subjects who were extensive metabolizers of debrisoquin. Each subject was studied on two occasions. On the first occasion, each subject received oral propranolol (80 mg) alone; on the second occasion, 7 days later, each subject received a dose of propranolol (80 mg) 30 minutes after the administration of oral debrisoquin (40 mg). Oral propranolol clearance was reduced 33% +/- 16% (p less than 0.05) by the administration of debrisoquin. As predicted, the 4-hydroxypropranolol partial metabolic clearance was significantly (p less than 0.05) inhibited by debrisoquin. However, the side-chain oxidation pathway, as measured by naphthoxylactic acid, was also significantly (p less than 0.05) inhibited by debrisoquin. Debrisoquin administration did not change the renal clearance of any of the metabolites. These data support the usefulness of the in vivo inhibition model in the prediction of cosegregation of routes of metabolism. However, for propranolol, pathways of its metabolism that are not thought to cosegregate with debrisoquin was also inhibited.

Influence of debrisoquin phenotype on the inducibility of propranolol metabolism.

The effects of rifampin (600 mg) once daily for 22 days on the total and fractional metabolic clearances of propranolol were determined in a group of six genetically extensive (EM) and six poor metabolizers (PM) of debrisoquin. The impaired ability of PMs to metabolize propranolol to the ring-oxidized metabolite 4-hydroxypropranolol was confirmed. The total oral clearance of propranolol increased about fourfold in both phenotypes from 219.2 +/- 52.8 to 976.7 L/hr in the EMs and from 75.0 +/- 12.6 to 289.8 +/- 78.2 L/hr in the PMs. The extent of induction of glucuronidation was similar in the two groups. 4-Hydroxylation was induced in both phenotypes but the increase was fifteenfold greater in EMs than in PMs. This would imply that the cytochrome P-450 determined by the debrisoquin allele or some coinherited 4-hydroxylase(s) was induced to a greater extent in EMs than PMs.

Effect of cirrhosis and debrisoquin phenotype on the disposition and effects of pinacidil.

Pinacidil is an investigational vasodilator currently undergoing clinical trials as an antihypertensive agent. It is metabolized in humans to pinacidil N-oxide. To determine whether pinacidil's metabolism or effects were influenced by either liver disease or the subject's debrisoquin phenotype, eight patients with chronic stable cirrhosis and 13 healthy subjects were studied. Seven of the healthy volunteers were extensive metabolizers of debrisoquin, whereas six were of the poor metabolizer phenotype. Neither the clearance of pinacidil nor the production of the N-oxide was altered by the subjects' debrisoquin phenotype. Cirrhosis produced a 50% reduction in pinacidil's clearance (20.7 +/- 1.4 vs. 42.1 +/- 5.1 L/hr; P less than 0.0005) and a prolongation in the elimination t1/2 from 3.9 +/- 0.3 to 6.1 +/- 0.6 hours (P less than 0.01). Less pinacidil was metabolized to the N-oxide metabolite in the patients with cirrhosis than in the normal individuals. Thus pinacidil's metabolism and clearance are reduced in patients with cirrhosis but are independent of debrisoquin phenotype.

In vivo modulation of CYP enzymes by quinidine and rifampin.

BACKGROUND: The metabolism of drugs and other xenobiotics is mediated by enzymes whose activities can be modulated by different compounds. The activities of these modulators have the potential to be used to optimize drug action, prevent toxicity, or identify the enzymes involved in a reaction. This approach requires that selective agents be used for specific enzymes. However, selectivity of action has been poorly characterized in vivo. METHODS: This study investigated the effect of 3 and 28 days of treatment with quinidine (200 mg daily) and rifampin (INN, rifampicin) (600 mg daily) on the activities of four cytochrome P450 enzymes and N-acetyltransferase in 28 healthy young male volunteers divided into three groups with a cocktail of drug probes used, including caffeine, mephenytoin, debrisoquin (INN, debrisoquine), and dapsone. RESULTS: Quinidine selectively and almost completely inhibited the activity of CYP2D6 from day 3 through day 28 without affecting any other enzymes. Rifampin showed evidence of time-dependent induction of the activities of all measured oxidative routes of metabolism but decreased the acetylation ratio in fast acetylators. The quinidine/rifampin combination resulted in selective CYP2D6 inhibition and induction of all other enzymes evaluated over this time period, suggesting that predictable complex interactions occur with the drug combination. CONCLUSIONS: These observations illustrate the value of simultaneous assessment of the effect of modulators on the activities of multiple specific enzymes with the drug cocktail approach.

Assessment of brain dopamine metabolism from plasma HVA and MHPG during debrisoquin treatment: validation in monkeys treated with MPTP.

Homovanillic acid (HVA) is formed from dopamine that escapes conversion to norepinephrine in noradrenergic neurons throughout the body as well as from dopamine synthesized in dopaminergic neurons that are mainly in brain. Debrisoquin has been used to diminish peripheral formation of dopamine to enhance the value of plasma HVA as an index of brain dopaminergic activity. This enhancement may be improved if the residual HVA formed in noradrenergic neurons could be estimated. By use of simultaneously measured plasma levels of the major metabolite of norepinephrine, the degree of residual catecholamine formation in noradrenergic neurons can be estimated. By extrapolating to zero MHPG levels the linear relationship of plasma HVA to plasma MHPG, an estimate of HVA formed solely from brain dopaminergic neurons can be obtained. This method was tested by administering debrisoquin to monkeys before and after destruction of brain dopaminergic neurons with MPTP. After MPTP treatment there were decreases in plasma HVA that were relatively greatest when considered in relation to MHPG. The results support the view that the plasma HVA levels at extrapolated zero MHPG levels improves precision in assessing brain dopamine metabolism.

Effects of monoamine oxidase inhibitors on levels of catechols and homovanillic acid in striatum and plasma.

Levels of homovanillic acid (HVA), dihydroxyphenylacetic acid (DOPAC) and dihydroxyphenylglycol (DHPG) in plasma and the striatium were measured after inhibition of monoamine oxidase type A (MAO-A) by clorgyline (4 mg/kg i.p.), MAO-B by (-)deprenyl (1 mg/kg i.p.), both MAO-A and MAO-B by nialamide (75 mg/kg i.p.) or peripheral neuronal MAO by debrisoquin (40 mg/kg i.p.). Levels of HVA in plasma decreased by about 60% after single doses of nialamide or clorgyline, by about 80% after repeated doses of nialamide, by about 40% after a single dose of debrisoquin and by about 50% after repeated doses of debrisoquin. The administration of clorgyline, nialamide or debrisoquin significantly decreased concentrations of DOPAC and DHPG in plasma, whereas (-)deprenyl did not affect levels of DHPG or HVA. None of the MAO inhibitors produced more than about 80% depression of levels of any of the deaminated metabolites. The results suggest that most of the HVA in plasma is derived from deamination of DA by MAO-A in peripheral neurons; that DOPAC in plasma is derived from cells outside the central nervous system; that DHPG in plasma is derived virtually exclusively from the metabolism of norepinephrine in sympathetic nerve endings and that residual levels of HVA after treatment with debrisoquin provide an improved but limited indication of central dopaminergic activity.

The sympathomimetic activity of fenfluramine hydrochloride on rat vas deferens.

1. The peripheral, pharmacological effects of the anorexigenic agent, fenfluramine hydrochloride, have been investigated on rat isolated vas deferens. 2. Characteristic spiked contractions were observed within 2 to 3 min after exposure to fenfluramine; these contractions reached a rate of around 13 per min and were of variable height. 3. Pre-treatment of vasa with the indirectly acting sympathomimetic amine, tyramine, greatly reduced both the height and rate of contraction induced by fenfluramine. 4. The uptake inhibitor, desipramine, required a concentration in excess of 10 micronM to affect fenfluramine-induced contractions. Effects of desipramine on fenfluramine contractions were of equal magnitude whether desipramine was administered before fenfluramine or at the height of the fenfluramine-induced contractions. 5. Pre-treatment with debrisoquine (0.5 mM), reduced the contractions in response to fenfluramine over a period of time. 6. Fenfluramine, added to vasa from rats which had been injected intraperitoneally with 5 mg/kg reserpine 24 h and 48 h previously, failed to induce its characteristic contractions. 7. It is concluded that fenfluramine can be classed as an indirectly acting sympathomimetic amine on peripheral adrenergic nerve terminals.

The relation between the adrenergic neurone-blocking and noradrenaline-depleting actions of some guanidine derivatives.

1 The effects of some guanidine derivatives, (-)-N-(1-phenylethyl) guanidine (PEG), guanethidine and debrisoquine have been investigated on the content and subcellular distribution of noradrenaline in cat spleen and on the overflow of noradrenaline from this organ during stimulation of the splenic nerve.2 PEG and guanethidine, at a dose of 5 mg/kg, produced adrenergic neurone blockade within 15 min and the same dose of debrisoquine produced blockade within 30 minutes.3 All three compounds produced a decrease of similar magnitude in the noradrenaline content of the high-speed particulate (P(2)) and supernatant (S) fractions of splenic homogenates; these actions were temporally correlated with the adrenergic neurone-blocking action of the compounds.4 PEG did not produce any further decrease in the noradrenaline content of the subcellular fractions at times up to 18 h after its administration; adrenergic neurone blockade was maintained throughout this period but had disappeared after 7 days when the noradrenaline content of the subcellular fractions was restored to control levels.5 Guanethidine, in contrast, caused a marked progressive loss of the transmitter from all subcellular fractions-an effect which was maximal 18 h after its administration but continued, as did the adrenergic neurone-blocking action, for at least 72 hours. This additional loss of noradrenaline, over and above that seen after 15 min, is unlikely to be connected with the adrenergic neurone-blocking action of the drug.6 Dexamphetamine both prevented and antagonized the neurone blockade and the subcellular noradrenaline-depleting action of PEG and guanethidine. The restoration of nerve function after administration of dexamphetamine to animals pretreated with 5 mg/kg of either of these compounds was temporally correlated with a selective repletion of the noradrenaline content of the supernatant fraction of the spleen.7 Larger doses (15 mg/kg) of PEG or guanethidine produced a selective depletion of noradrenaline in only the supernatant fraction of the spleen. This depletion was temporally correlated with the adrenergic neurone-blocking action of these compounds. The lack of effect of the compounds at this dose level on the noradrenaline contained in the P(2) fraction may be due to ;stabilization' of the store of noradrenaline in vivo which gives rise to this fraction on homogenization.8 It is suggested that the guanidine-type adrenergic neurone-blocking agents displace the noradrenaline which is readily available for release by nerve impulses, and that it is this action that may account for their sympathomimetic properties.9 The ability of these guanidines to impair the release of noradrenaline by nerve impulses could occur because whilst they are present within the neurone the ;nerve-releasable store', which may in these experiments appear in the supernatant fraction after homogenization, may be unable to refill with transmitter.

Metoprolol oxidation by rat liver microsomes. Inhibition by debrisoquine and other drugs.

The oxidative metabolism of metoprolol has been shown to display genetic polymorphism of the debrisoquine-type. The use of in vitro inhibition studies has been proposed as a means of defining whether one or more forms of cytochrome P-450 are involved in the monogenically-controlled metabolism of two substrates. We have, therefore, tested the ability of debrisoquine and other substrates to inhibit the oxidation of metoprolol by rat liver microsomes. Debrisoquine and guanoxan were potent competitive inhibitors of the alpha-hydroxylation and O-desmethylation of metoprolol as well as its metabolism by all routes (measured by substrate disappearance). Cimetidine and ranitidine, drugs which are known to impair the clearance of metoprolol in man, showed an inhibitory action comparable to that of debrisoquine in rat liver microsomes. Antipyrine, a compound whose metabolism is not impaired in poor metabolisers of debrisoquine, was found to be only a weak inhibitor of the metabolism of metoprolol. These findings suggest that the oxidation of metoprolol is linked closely to that of debrisoquine, cimetidine and ranitidine but not to that of antipyrine in the rat.

Irreversible binding and metabolism of propranolol by human liver microsomes--relationship to polymorphic oxidation.

Studies were performed to investigate the irreversible binding and oxidative metabolism of propranolol in human liver microsomes and the relationship of binding and metabolism to the polymorphic oxidation of debrisoquine. Incubation of microsomes with 14C-labelled propranolol in the presence of a NADPH-generating system gave rise to irreversible binding which increased linearly with time and became saturated at high substrate concentrations. The extent of binding was decreased by the exclusion of cofactors, boiling, anaerobic conditions, and the addition of reduced glutathione and SKF-525A. Trichloropropene oxide had a negligible effect on cofactor-dependent binding. However, debrisoquine, antipyrine and phenacetin decreased binding to a considerable extent. The latter compound abolished cofactor-dependent binding completely at the concentration used (1 mM). Electrophoresis of microsomes which had been incubated with tritiated propranolol revealed that binding was probably occurring to a large number of proteins particularly in the 40,000-90,000 molecular weight range. Glutathione, debrisoquine and antipyrine did not inhibit the 4'-hydroxylation and N-deisopropylation of propranolol. In contrast, phenacetin exerted a very potent inhibitory action on both routes of metabolism. It is concluded that a product or products of propranolol oxidation bind irreversibly but non-selectively to human liver microsomal protein, the enzyme system responsible for the activation of propranolol appears to be related more closely to the cytochrome P-450 system which metabolizes phenacetin than to that metabolising debrisoquine, and radiolabelled propranolol is not a sufficiently specific probe for studying these cytochrome P-450 systems.

Effects of debrisoquin on the excretion of catecholamine and octopamine metabolites in the rat and guinea pig.

The effects of debrisoquin, administered daily for 4 days to rats (40 mg/kg, i.p.) and guinea pigs (4 mg/kg, i.p.), were determined for urinary excretion of several acidic and neutral amine metabolites, including the norepinephrine metabolites, 3-methoxy-4-hydroxyphenethylene glycol (MHPG) and vanillylmandelic acid (VMA), the dopamine metabolites, 3,4-dihydroxyphenethanol (DHPE), 3-methoxy-4-hydroxyphenethanol (MHPE), and homovanillic acid (HVA), and the octopamine metabolite, p-hydroxyphenylglycol (pHPG). The excretion of MHPG was reduced to 32% of control in rats and to 46% in guinea pigs, HVA was reduced to 64 and 80% in these two species, respectively, and MHPE was lowered to 59% of control in the rat but was not affected in the guinea pig. DHPE and pHPG were not altered significantly in either species. VMA was a minor metabolite in both species, being less than 6% of MHPG, and its formation was blocked only partially (rat) or not at all (guinea pig) by debrisoquin. The data refute the idea based on previous in vitro studies that VMA is a major metabolite of norepinephrine in the periphery of the guinea pig as it is in man.

Plasma homovanillic acid as an index of central dopaminergic activity: studies in schizophrenic patients.

Despite the limitations of the dopamine hypothesis, compelling evidence remains that implicates dysfunction of CNS dopamine systems in the pathophysiology of schizophrenia. The longitudinal measurement of levels of plasma HVA has proved a useful tool in studying neuroleptic effects and has highlighted time-dependent effects as a potentially important facet of the mechanism of antipsychotic action of these drugs. Despite the good clinical correlates of plasma HVA levels, caution is needed in interpreting plasma levels of HVA with regard to CNS dopamine activity. The peripheral nervous system significantly contributes to levels of HVA that circulate in plasma. This issue is underscored by the fact that CSF HVA shows different neuroleptic response patterns than that seen in plasma. The administration of a peripherally acting MAO inhibitor to enhance the CNS "signal" in circulating levels of HVA does not resolve the "problem" of different CSF-plasma HVA neuroleptic response patterns. The possibility that mesocortical dopamine activity is reflected by CSF HVA is suggested by indirect evidence from clinical and preclinical studies. Future studies in which attempts are made at using both plasma and CSF HVA to enhance neurochemical and clinical correlates may help to advance our understanding of the contributions of specific CNS dopamine systems to schizophrenia.

The activity of the sympathetic nervous system following severe head injury.

The activity of the sympathetic nervous system during the course of severe closed head injury has been evaluated in 15 patients by measuring plasma levels of epinephrine and norepinephrine. With the onset of the transition stage from midbrain syndrome to the apallic syndrome the plasma levels mainly of norepinephrine started to increase and remained high during the further course of the disease. During the remission from the apallic syndrome the elevated norepinephrine levels started to decline. The data indicate that a longlasting overactivity of the sympathetic nervous system is a characteristic feature in the course of severe head injury. As a rational therapy to protect the peripheral tissues against the consequences of a longlasting sympathetic overactivity we suggest the use of beta-adrenergic blocking agents and adrenergic neuron blocking drugs.

Assessment of in vivo CYP2D6 activity: differential sensitivity of commonly used probes to urine pH.

Drug/metabolite ratios (MRs) are used as in vivo markers of enzyme activity. The ratios are potentially confounded by the renal clearance of the drug (urine-based MRs) or metabolite (plasma-based MRs). The authors have investigated the relative sensitivity of urinary MR of 3 in vivo probe substrates of CYP2D6 debrisoquine (DB), dextromethorphan (DM), and metoprolol (MP) to changes in urine pH. Three groups of healthy volunteers each comprising 12 individuals were given DB (10 mg), DM (25 mg), or MP (100 mg) on 3 occasions. In 1 study arm, urine was acidified by the oral intake of ammonium chloride; in another, it was alkalinized by intake of sodium bicarbonate; and in the third, urine pH was uncontrolled. Urinary MP/alpha-hydroxy-MP, DM/dextrorphan, and DB/4-hydroxy-DB ratios were calculated. The mean(geo) MR for DB was not significantly different in any of the study arms, whereas those for MP and DM were significantly different under acidified and alkalinized urine conditions compared to uncontrolled urine pH (P < .01) and were correlated with urine pH (P < .001). Without control of urine pH, in vivo estimates of CYP2D6 metabolic activity are likely to be less precise using DM or MP as probe substrates compared to DB. Although this is unlikely to cause any problem in distinguishing the large functional differences in CYP2D6 in poor metabolizer (PM) and extensive metabolizer (EM) phenotypes, this may contribute to difficulties in differentiating in vivo metabolic activity among allelic variants within the overall CYP2D6 EM phenotype using MP or DM. However, because DB is not available in many countries (eg, United States), alternative in vivo markers of CYP2D6 with low sensitivity to urine pH should be sought.